Five-term karatsuba-variant calculator

ABSTRACT

A technology generally related to large-scale computations employed in the fields of cryptography and data security system employing a new and improved variant of the Karatsuba multiplication approach. The variant of the Karatsuba multiplication approach being utilized to minimize the number of coefficient multiplications needed to multiple two polynomials of degree four.

TECHNICAL FIELD

This invention generally relates to technology involving large-scale computations.

BACKGROUND

Multiplying two polynomials (or integers) efficiently is a key issue in a variety of academic fields and practical applications. Examples of such fields and applications include (but are not limited to): signal processing, cryptography, digital security systems, computer science, and number theory.

Multiplication—Classic Schoolbook Style

The conventional (i.e., “classic schoolbook” style) of multiplication in positional number systems requires approximately c*m*n operations to multiply an m-place (e.g., m-digits) number by an n-place (e.g., n-digits) number, for some constant c. When m=n, this conventional procedure for multiplication of two n-place numbers requires an execution time approximately proportional to n², as n increases. This cost is sometimes written O(n²).

Put another way, this classic schoolbook approach of multiplication of two n-digit numbers results in a cost of n² operations. The overall cost of the big multiplication is the number of basic operations (e.g., addition, subtraction, and multiplication of single-digit numbers) required to complete a task; however, often the focus is on the multiplication tasks since those typically dominate the running time. The task in this case is the multiplication of two n-digit numbers.

This conventional multiplication approach has many different names. For example, it may be called “brute-force”, “long”, “classic”, and such. Herein, it is referred to as “classic schoolbook” multiplication.

It is also used for the multiplication of polynomials. For example, let n be a positive integer. The “classic schoolbook” way to multiply two univariate polynomials of degree at most n−1 (i.e., with n terms each, some of whose coefficients may be zero) needs n² multiplications of coefficients. It multiplies each coefficient of one polynomial by each coefficient of the other, adding the products where needed.

If a(X)=a₁X+a₀ and b(X)=b₁X+b₀ are two linear polynomials in the same variable X, then the “classic schoolbook” approach computes all three coefficients of the product polynomial a(X)b(X)=a₁b₁X²+(a₁b₀+a₀b₁)X+a₀b₀ with four multiplications of the original coefficients, followed by one addition. As discussed later, other approaches need only three coefficient multiplications.

Fast Multiplication—Karatsuba Style

In 1962, A. Karatsuba and Yu. Ofman suggested (in Doklady Akad. Nauk SSSR 145 (1963), 293-294) a new multiplication technique that had an overall asymptotic cost less than the classic schoolbook's O(n²). Since 1962, many variants of Karatsuba have been proposed. This is described further by Donald E. Knuth in his “The Art of Computer Programming”, Volume 2, Seminumerical Algorithms, Third Edition, Addison-Wesley 1998). More on the Karatsuba-style multiplication appears in “Generalizations of the Karatsuba Algorithm for Efficient Implementations” by André Weimerskirch and Christof Paar (http://www.crypto.ruhr-uni-bochum.de/Publikationen/texte/kaweb.pdf).

In terms of efficiency, the Karatsuba-style multiplication approach (with its existing variants) is an improvement over the classic schoolbook approach. Just like back in 1962 when Karatsuba suggested a new approach, it is still desirable to improve the efficiency (and thus speed) of multiplication.

SUMMARY

A technology generally related to large-scale computations is described herein. For example, one implementation, described herein, may be employed in the fields of cryptography and digital security systems. An implementation, described herein, employs a new and improved variant of the Karatsuba multiplication approach.

BRIEF DESCRIPTION OF THE DRAWINGS

The same numbers are used throughout the drawings to reference like elements and features.

FIG. 1 shows an example of a system that may employ a Karatsuba-variant calculator in accordance with an implementation described herein.

FIG. 2 is a flow diagram showing a methodological implementation described herein.

FIG. 3 is an example of a computing operating environment capable of (wholly or partially) implementing at least one embodiment described herein.

DETAILED DESCRIPTION

The following description sets forth techniques for performing a five-term Karatsuba-Variant calculation. The techniques may be implemented in many ways, including on computing systems or computer networks, as part of digital security, anti-piracy, cryptography architectures, systems, and/or applications.

An example of an embodiment, described herein, may be referred to as an “exemplary Karatsuba-variant calculator.”

Minimum Multiplications Function M(n)

Given a positive integer n, let M(n) denote the minimum number of coefficient multiplications needed to multiply two polynomials of degree at most n−1. Sometimes, polynomials of degree at of degree at most n−1 are described as polynomials having n terms each (where some coefficients may be zero).

M(1)=1 may be described, in words, as multiplication of two constant polynomials, having one term each, that results in a minimum of one coefficient multiplication. This situation is trivial. Since degree-zero polynomials are scalars, one simply multiplies the two scalars.

“Classic Schoolbook” is Not Optimal

The “classic schoolbook” approach shows that M(n)≦n² for all n. In particular M(2)≧4. However we can achieve M(2)≦3.

Consider the two linear polynomials a(X)=a₁X+a₀ and b(X)=b₁X+b₀ in the same variable X. Their product is a(X)b(X)=(a ₁ X+a ₀)(b ₁ X+b ₀)=a ₁ b ₁ X ²+(a ₁ b ₀ +a ₀ b ₁)X+a ₀ b ₀. Instead of computing all four products a₁b₁, a₁b₀, a₀b₁, a₀b₀, one can start with a₁b₁ and a₀b₀. Use the identity a ₁ b ₀ +a ₀ b ₁=(a ₁ +a ₀)(b ₁ +b ₀)−a ₁ b ₁ −a ₀ b ₀. This identity replaces two multiplications (namely, a₁b₀ and a₀b₁) by the single multiplication (a₁+a₀)(b₁+b₀) and some additions (herein, “addition” operations also encompass “subtraction” operations).

We can summarize this computation with

$\begin{matrix} {{\left( {{a_{1}X} + a_{0}} \right)\left( {{b_{1}X} + b_{0}} \right)} = {{a_{0}{b_{0}\left( {{- X} + 1} \right)}} + {\left( {a_{1} + a_{0}} \right)\left( {b_{1} + b_{0}} \right)X} + {a_{1}{b_{1}\left( {X^{2} - X} \right)}}}} & \lbrack 1\rbrack \end{matrix}$

Within Equation 1, the (−X+1) factor after a₀b₀ signifies that a₀b₀ appears with a minus sign in the coefficient of X¹ and with a plus sign in the coefficient of X⁰=1. The product (a₁+a₀)(b₁+b₀) is used only once, with a plus sign in the coefficient of X¹. The product a₁b₁ appears with a plus sign in the coefficient of X² and with a minus sign in the coefficient of X¹.

The three products used are a₀b₀, (a₁+a₀)(b₁+b₀), and a₁b₁. The first two products are a(0)b(0) and a(1)b(1), the values of the quadratic polynomial a(X)b(X) evaluated at X=0 and X=1. The last product, a₁b₁, may be interpreted as a(∞)b(∞), the most significant coefficient of the product. The product polynomial (degree at most 2 for this example) is uniquely determined by its values at three distinct points.

By replacing X by −X, a₁ by −a₁ and b₁ by −b₁, another formula is derived that uses only three multiplications:

$\begin{matrix} {{\left( {{a_{1}X} + a_{0}} \right)\left( {{b_{1}X} + b_{0}} \right)} = {{a_{0}{b_{0}\left( {X + 1} \right)}} + {\left( {a_{1} - a_{0}} \right)\left( {b_{1} - b_{0}} \right)({\_ X})} + {a_{1}{{b_{1}\left( {X^{2} + X} \right)}.}}}} & \lbrack 2\rbrack \end{matrix}$ Higher Degree—M(n)≦n(n+1)/2 Let n be an arbitrary positive integer. The technique in the last section generalizes to show M(n)≦n(n+1)/2. Given two input polynomials

${a(X)} = {{\sum\limits_{0 \leq i \leq {n - 1}}^{\;}\;{a_{i}X^{i}\mspace{14mu}{and}\mspace{14mu}{b(X)}}} = {\sum\limits_{0 \leq j \leq {n - 1}}^{\;}\;{b_{j}{X^{j}.}}}}$ of degree at most n−1, the product is

$\begin{matrix} {{{a(X)}{b(X)}} = {\sum\limits_{0 \leq i \leq {n - 1}}^{\;}{\sum\limits_{0 \leq j \leq {n - 1}}^{\;}{a_{i}b_{j}X^{i + j}}}}} \\ {= {{\sum\limits_{0 \leq i \leq {n - 1}}^{\;}{a_{i}b_{i}X^{2i}}} + {\sum\limits_{0 \leq i \leq {n - 1}}^{\;}{\left( {{a_{i}b_{j}} + {a_{j}b_{i}}} \right)X^{i + j}}}}} \end{matrix}$

To elaborate further: Once all products of the form a_(i)b_(i) are evaluated, each a_(i)b_(j)+a_(j)b_(i) where i<j may be evaluated using one of the identities a _(i) b _(j) +a _(j) b _(i)=(a _(i) +a _(j))(b _(i) +b _(j))−a _(i) b _(i) −a _(j) b _(j) or a _(i) b _(j) +a _(j) b _(i) =a _(i) b _(i) +a _(j) b _(j)−(a _(i) −a _(j))(b _(i) −b _(j)).

This approach has n products of the form a_(i)b_(i) and another

$\frac{n\left( {n - 1} \right)}{2}$ of the form (a_(i)+a_(j))(b_(i)+b_(j)) or (a_(i)−a_(j))(b_(i)−b_(j)), for a combined

$\frac{n\left( {n + 1} \right)}{2}$ products. Example: n=3

When n=3, this approach achieves 6 scalar multiplications (rather than the 9 multiplications used by the classic schoolbook approach). If we start with a(X)=a₂X²+a₁X+a₀ and b(X)=b₂X²+b₁X+b₀, then the product is

a(X)b(X) = (a₂X² + a₁X + a₀)(b₂X² + b₁X + b₀) = a₂b₂X⁴ + (a₂b₁ + a₁b₂)X³ + (a₂b₀ + a₁b₁ + a₀b₂)X² + (a₁b₀ + a₀b₁)X + a₀b₀. To compute all five coefficients, start with a₂b₂, a₁b₁, and a₀b₀. Use the technique in the last section three times. a ₂ b ₁ +a ₁ b ₂=(a ₂ +a ₁)(b ₂ +b ₁)−a ₂ b ₂ −a ₁ b ₁ a ₂ b ₀ +a ₀ b ₂=(a ₂ +a ₀)(b ₂ +b ₀)−a ₂ b ₂ −a ₀ b ₀ a ₁ b ₀ +a ₀ b ₁=(a ₁ +a ⁰)(b ₁ +b ₀)−a ₁ b ₁ −a ₀ b ₀. This construction shows M(3)≦6.

(a₂X² + a₁X + a₀)(b₂X² + b₁X + b₀) = a₀b₀(1 − X − X²) + a₁b₁(−X + X² − X³) + a₂b₂(−X² − X³ + X⁴) + (a₁ + a₀)(b₁ + b₀)X + (a₂ + a₀)(b₂ + b₀)X² + (a₂ + a₁)(b₂ + b₁)X³. If we instead use the identities a ₂ b ₁ +a ₁ b ₂ =a ₂ b ₂ +a ₁ b ₁−(a ₂ −a ₁)(b ₂ −b ₁) a ₂ b ₀ +a ₀ b ₂ =a ₂ b ₂ +a ₀ b ₀−(a ₂ −a ₀)(b ₂ −b ₀) a ₁ b ₀ +a ₀ b ₁ =a ₁ b ₁ +a ₀ b ₀−(a ₁ −a ₀)(b ₁ −b ₀), then we end up with

(a₂X² + a₁X + a₀)(b₂X² + b₁X + b₀) = a₀b₀(1 + X + X²) + a₁b₁(X + X² + X³) + a₂b₂(X² + X³ + X⁴) − (a₁ − a₀)(b₁ − b₀)X − (a₂ − a₀)(b₂ − b₀)X² − (a₂ − a₁)(b₂ − b₁)X³. Fast Multiplication via Recursion—Karatsuba Style

So far our bound M(n)≦n(n+1)/2 remains O(n²), like the O(n²), time of the “classic schoolbook” method but with a smaller constant factor. Karatsuba and Ofman demonstrated that the asymptotic cost may be improved using recursion when n is composite.

The bound M(n)≦n(n+1)/2 gives M(4)≦10. The recursive algorithm will show M(4)≦M(2)²≦9. Consider the two four-term (degree≦3) polynomials: a(X)=a ₃ X ³ +a ₂ X ² +a ₁ X+a ₀ and b(X)=b ₃ X ³ +b ₂ X ² +b ₁ X+b ₀ Letting Y denote X², these may be rewritten as: a(X,Y)=(a ₃ X+a ₂)Y+(a ₁ X+a ₀) and b(X,Y)=(b ₃ X+b ₂)Y+(b ₁ X+b ₀).

Note that a(X) originally has 4 terms. Group the degree 2 and degree 3 terms together and factor out an X²=Y. Now a(X) is expressed as a linear polynomial in Y with coefficients which are polynomials in X. Later, Y may be replaced by X². View the intermediate a(X,Y) and b(X,Y) as linear polynomials in the variable Y, with polynomial coefficients in the variable X.

After doing the three multiplications (a ₃ X+a ₂)(b ₃ X+b ₂) (a ₁ X+a ₀)(b ₁ X+b ₀) (a ₃ X+a ₂ +a ₁ X+a ₀)(b ₃ X+b ₂ +b ₁ X+b ₀) (products of linear polynomials in the variable X) and doing a few more additions (of quadratic polynomials in X), one obtains the polynomial product a(X,Y)b(X,Y). If Y is replaced by X² and a few more additions are done (by combining terms with the same power of X), then one obtains a(X)b(X). In doing so, one uses only nine multiplications in the base field (or ring), three for each product of two linear polynomials in X. Therefore M(4)≦9. Example

For example, to form the product a(X)b(X) where a(X)=3X ³ +X ²+4X+1 and b(X)=5X ³+9X ²+2X+6,

this approach uses the three products (3X+1)(5X+9)=15X ²+32X+9 (4X+1)(2X+6)=8X ²+26X+6 (7X+2)(7X+15)=49X ²+119X+30

In this example, the polynomial product (3X+1)(5X+9) (for example) needs only the three coefficient multiplications: 3×5=15, (3+1)×(5+9)=4×14=56 and 1×9=9. The middle coefficient of that product is 56−15−9=32. Similar observations apply to the other two products of linear (in X) factors.

At the next level, the middle coefficient is (49X ²+119X+30)−(15X ²+32X+9)−(8X ²+26X+6)=26X ²+61X+15 and the product a(X)b(X) is (with Y=X²):

$\begin{matrix} {{{a(X)}{b(X)}} = {{\left( {{15X^{2}} + {32X} + 9} \right)Y^{2}} + {\left( {{26X^{2}} + {61X} + 15} \right)Y} + \left( {{8X^{2}} +} \right.}} \\ \left. {{26X} + 6} \right) \\ {= {{15X^{6}} + {32X^{5}} + {\left( {9 + 26} \right)X^{4}} + {61X^{3}} + {\left( {15 + 8} \right)X^{2}} +}} \\ {{26X} + 6} \\ {= {{15X^{6}} + {32X^{5}} + {35X^{4}} + {61X^{3}} + {23X^{2}} + {26X} + 6.}} \end{matrix}$ Basis for Recursion—M(n₁n₂)≦M(n₁)M(n₂)

The last construction illustrates how one can multiply two polynomials each with n₁n₂ terms using M(n₁) multiplications of polynomials of with n₂ terms, by breaking the input into n₁ blocks each of length n₂.

A corollary is M(n₁n₂)≦M(n₁)M(n₂).

In particular, when n=2^(k) is a power of 2, this recursive technique multiplies two polynomials of degree at most n−1 with M(2)^(k)≦3^(k)≈n^(1.585) multiplications rather than the brute-force n²=4^(k) multiplications of the classic schoolbook approach.

Lowering the asymptotic exponent from 2 to 1.585 makes an enormous difference when n is large. Even for the modest n=2⁵=32, this technique uses 243 multiplications rather than 1024, a four-fold improvement. This is a simple example of high-speed multiplication.

So far we have glossed over the number of additions needed. If n is a power of 2 and A(n) denotes the number of coefficient additions needed to multiply two polynomials of degree at most n−1 by this method, then A(1)=0 and A(2n)=3A(n)+8n−4. The solution is A(2^(k))=6*3^(k)−8*2^(k)+2, approximately six times the number of multiplications used.

Handling Odd Degrees

It is easy to show M(2n+1)≦M(n)+2M(n+1). Each input polynomial with 2n+1 terms is split into one piece with n terms and one piece with n+1 terms.

Proceeding recursively then gives an overall cost of O(n^(lg 3))≈O(n^(1.585)) where lg denotes base-2 logarithm, even if n is not restricted to powers of 2.

Multiplication by Interpolation

Interpolation approaches, such as that described Section 3.7.3, p.79 of H. J. Nussbaumer (“Fast Fourier Transform and Convolution Algorithms”, 2^(nd) Ed., Spirnger-Verlag, Berlin, 1982), give a formula for multiplying two quadratic polynomials with five multiplications (rather than the six multiplications required by the conventional approach) when one of the two input polynomials will be (re)used for several different products. Nussbaumer evaluates the degree-4 product at five values of X (namely at −1, 0, 1, 2, and ∞), interpolating to get the five output coefficients.

However, Nussbaumer's formula requires a division by 6. Such divisions are not allowed in characteristics 2 and 3 algebras. The five points of evaluation are not distinct in characteristics 2 and 3.

Known Upper Bounds on M(n) for Small n

Using the results so far, the following table represents the bounds:

TABLE I n 2 3 4 5 6 7 8 M(n) ≦ 3 6 9 15 18 24 27 Reason * * * 5(5 + 1)/2 or M(2)M(3) M(3) + 2M(4) M(2)M(4) M(2) + 2M(3) * = Reason discussed above These bounds agree with those in Appendix A of Weimerskirch and Paar. Cryptographic Applications of Polynomial Multiplication

Cryptographic applications of polynomial multiplication include large integer multiplication and finite field arithmetic. We describe those briefly below.

Application to Large Integer Multiplication

Some cryptographic algorithms such as RSA require multiplication of large integers. The inputs may be 1024-bit integers or larger. Typically, these numbers are represented in radix 2³² or 2⁶⁴ within a computer, requiring 32 (=1024/32) or 16 (=1024/64) words to represent each 1024-bit number.

For example, fix a base R and a length n. To multiply two large integers A and B between 0 and R^(n)−1, start with their radix-R representations

$A = {{\sum\limits_{0 \leq i \leq {n - 1}}^{\;}\;{a_{i}R^{i}\mspace{14mu}{and}\mspace{14mu} B}} = {\sum\limits_{0 \leq i \leq {n - 1}}^{\;}\;{b_{j}R^{j}}}}$ where 0≦a_(i)<R and 0≦b_(j)<R.

Two polynomials are introduced here:

${a(X)} = {{\sum\limits_{0 \leq i \leq {n - 1}}^{\;}\;{a_{i}X^{i}\mspace{14mu}{and}\mspace{14mu}{b(X)}}} = {\sum\limits_{0 \leq i \leq {n - 1}}^{\;}\;{b_{j}X^{j}}}}$

These polynomials are selected so that A=a(R) and B=b(R). Compute the polynomial product a(X)b(X) and substitute X=R. With those changes, these polynomials may be rewritten:

$A = {{a(R)} = {{\sum\limits_{0 \leq i \leq {n - 1}}^{\;}\;{a_{i}R^{i}{\mspace{11mu}\;}{and}\mspace{14mu} B}} = {{b(R)}{\sum\limits_{0 \leq i \leq {n - 1}}^{\;}{b_{j}R^{j}}}}}}$

Those who are skilled in the art are familiar with additional details necessary to perform this sort of large integer multiplications at this point. Examples of such details are found in Chapter 8 of Alfred V. Aho, John E. Hopcroft, & Jeffrey D. Ullman, “The Design and Analysis of Computer Algorithms”, Addison-Wesley, Reading, Mass., 1974.

Example

For example, to multiply the two integers A=3141 and B=5926 in radix R=10, one starts with a(X)=3X ³ +X ²+4X+1 and b(X)=5X ³+9X ²+2X+6.

These polynomial coefficients come directly from the decimal expansions of A and B. As in an earlier example, form the polynomial product a(X)b(X)=15X ⁶+32X ⁵+35X ⁴+61X ³+23X ²+26X+6 (nine multiplications of coefficients suffice). Substitute X=10 to get

$\begin{matrix} {{AB} = {{{a(10)}{b(10)}} = {15000000 + 3200000 + 350000 + 61000 +}}} \\ {2300 + 260 + 6} \\ {= 18613566.} \end{matrix}$

Because coefficients of the polynomial product a(X)b(X) may exceed R−1, carry propagation is needed during the final phase. For example, the 6 from 61 in 61X³ is added to the 35 from 35X⁴, giving 41—this 1 is part of the product and the 4 is added to the 32 from 32X⁵.

Finite Field Extensions

Another application of polynomials occurs when taking extensions of a finite field. Let p be a prime. Set K=GF(p), the finite field with p elements. Choose an extension degree m>0 and an irreducible polynomial F(X) of degree m over K. The extension GF(p^(m)) consists of all polynomials of degree at most m−1, with coefficients in the finite ring K.

To multiply two elements of GF(p^(m)), form their polynomial product (of degree at most 2m−2) and reduce this product modulo F(X), aiming for (close to) M(m) multiplications in the base field K. The field polynomial F(X) is often chosen to make the reduction step easy (e.g., by having few nonzero coefficients).

Arithmetic in GF(2^(m))

Today's high-performance computers typically use binary arithmetic, in which each bit has exactly two possible values. Standard approaches for elliptic curve cryptosystems allow arithmetic modulo prime p or over a field GF(2^(m)). Two encodings for elements of GF(2^(m)) (polynomial basis or normal basis) are often used—a polynomial basis is assumed.

It takes m bits to store an arbitrary element of GF(2^(m)). On a b-bit computer (where b is typically 32 or 64, but may take other values), these bits fit in n=CEIL(m/b) words. [CEIL(x) rounds its real argument x up to the next integer.] The polynomial basis encoding of a typical field element: α=Σ _(0≦i≦m−1)α_(i) X ^(i) (each α_(i)=0 or 1) can store α₀ to α_(b−1) in one b-bit computer word, then α_(b) to α_(2b−1) in another word, etc. The (high-order) (n−1)-th word uses only m−(n−1)b of its b bits—with the unused bits typically set to zero.

For example, if b=32 and m=163, then n=CEIL(163/32)=6 words suffice to hold an arbitrary element of GF(2¹⁶³) on a 32-bit machine. Five words hold 32 bits each. The sixth word holds 3 bits (coefficients of X¹⁶⁰ to X¹⁶²), with its other 29 bits unused.

This encoding makes addition of two field elements very easy—it corresponds to n applications of the bitwise exclusive “OR” instruction found on most binary machines (one exclusive OR per word).

Subtraction is the same as addition in this algebra: x+y=x−y for all x, y ∈ GF(2^(m)). In particular, 1+1=0.

The polynomial multiplication operates on polynomials with b bits per input coefficient. An earlier section described how to multiply two polynomials each with n₁n₂ terms using M(n₁) multiplications of polynomials of degree at most n₂−1, by breaking the input into n₁ blocks each of length n₂. Apply that construction with n₁=n and n₂=b. Use a specialized method for multiplying two b-term polynomials (stored in b-bit words) over GF(2), invoking that method M(n) times. Pad the original operands with nb−m leading zeros. As in the integer arithmetic section, carry propagation is needed on the outputs since the output coefficients have 2b−1 bits each.

Exemplary Computation System

The one or more exemplary implementations, described herein, of the present claimed invention may be implemented (in whole or in part) by a Karatsuba-variant calculation unit 130 and/or by a computing environment like that shown in FIG. 3.

FIG. 1 shows an example of a computation system 100 that employs the Karatsuba-variant calculation unit 130. Such a system may be used to compute large integers and/or polynomials. It may also be used for multiplication computations in finite field extensions.

The system includes an input unit 110 for receiving the input data to be calculated. It has a memory 120 and the Karatsuba-variant calculation unit 130. It also has an output unit 140 for communicating the results of such calculations.

Exemplary Karatsuba-Variant Calculator

The exemplary Karatsuba-variant calculator herein has one or more embodiments to multiply pairs of polynomials with five terms each (i.e., pairs of polynomials of degree at most 4). It achieves M(5)≦13, compared with the M(5)≦15 in Table 1 above. These embodiments may work in arbitrary characteristic—all coefficients are integers, so there are no divisions. Like the original Karatsuba, it does not assume multiplication is commutative. These embodiments may be used in recursive constructions to achieve, for example, M(9)≦M(4)+2M(5)≦9+2*13=35, M(10)≦M(2)M(5)≦3*13=39, M(11)≦M(5)+2M(6)≦13+2*18=49, M(15)≦M(3)M(5)≦6*13=78. All of these beat the M(n)≦n(n+1)/2 bound

Although the exemplary Karatsuba-variant calculator, described herein, is valid in any characteristic, it is especially useful in characteristic 2 or 3, meaning algebras in which 1+1=0 or 1+1+1=0. For an application of characteristic 3 fields to cryptography, see “Implementing the Tate Pairing” by Steven D. Galbraith et al in Algorithmic Number Theory, 5th International Symposium, ANTS V, Sydney, Australia, July, 2002, Springer-Verlag LNCS 2369, pp. 324-337.

FIG. 1 shows an example of a computation system 100 that employs the Karatsuba-variant calculation unit 130. Such a system may be used to compute large integers and/or polynomials. It may also be used for multiplication computations in finite field extensions.

The system includes an input unit 110 for receiving the input data to be calculated. It has a memory 120 and the Karatsuba-variant calculation unit 130. It also has an output unit 140 for communicating the results of such calculations.

Pairwise Multiplication

The calculations of the exemplary Karatsuba-variant calculator may be performed recursively. The product of two one-term (i.e., constant polynomials) is found using multiplication in over the ring in which the coefficients lie. But the more complicated (a₁X+a₀)(b₁X+b₀) requires three products, namely a₀b₀, (a₁+a₀)(b₁+b₀), and a₁b₁.

These three products are done by invoking the algorithm recursively. As we do so, we append the three pairs of inputs (a₀,b₀), (a₁+a₀,b₁+b₀) , and (a₁,b₁) to a queue of products we're waiting on. The subsequent processing of these pairs may insert additonal entries in the waiting list. Once all three products have been completed, the procedure which queued them can complete its task.

Exemplary Karatsuba-Variant Calculator

The Karatsuba-variant calculation unit 130 of the computation system 100 employs an improved variant of the Karatsuba multiplication approach. More specifically, the Karatsuba-variant calculation unit 130 employs the exemplary Karatsuba-variant calculator, as described herein, which is generalized for any n-digit number or n-term polynomial, where n is a positive integer.

Five-term Karatsuba-variant Calculator using ≦13 Multiplications

The following describes a particular embodiment of the Karatsuba-variant calculator. In particular, the embodiment described is one for multiplying two polynomials with degree below 5. Therefore, this may be called an exemplary 5-term Karatsuba-variant calculator.

Two polynomials in the variable X, each with degree at most 4 (i.e., 5-term polynomials in X) are described as follows: a(X)=a ₀ +a ₁ X+a ₂ X ² +a ₃ X ³ +a ₄ X ⁴  [3] and b(X)=b ₀ +b ₁ X+b ₂ X ² +b ₃ X ³ +b ₄ X ⁴  [4]

Given that description of the 5-term polynomials, the equation for the exemplary 5-term Karatsuba-variant calculator is

$\begin{matrix} {{{a(X)}{b(X)}} = {{\left( {a_{0} + a_{1} + a_{2} + a_{3} + a_{4}} \right)\left( {b_{0} + b_{1} + b_{2} + b_{3} + b_{4}} \right)\left( {X^{5} - X^{4} + X^{3}} \right)} + {\left( {a_{0} - a_{2} - a_{3} - a_{4}} \right)\left( {b_{0} - b_{2} - b_{3} - b_{4}} \right)\left( {X^{6} - {2X^{5}} + {2X^{4}} - X^{3}} \right)} + {\left( {a_{0} + a_{1} + a_{2} - a_{4}} \right)\left( {b_{0} + b_{1} + b_{2} - b_{4}} \right)\left( {{- X^{5}} + {2X^{4}} - {2X^{3}} + X^{2}} \right)} + {\left( {a_{0} + a_{1} - a_{3} - a_{4}} \right)\left( {b_{0} + b_{1} - b_{3} - b_{4}} \right)\left( {X^{5} - {2X^{4}} + X^{3}} \right)} + {\left( {a_{0} - a_{2} - a_{3}} \right)\left( {b_{0} - b_{2} - b_{3}} \right)\left( {{- X^{2}} + {2X^{5}} - X^{4}} \right)} + {\left( {a_{1} + a_{2} - a_{4}} \right)\left( {b_{1} + b_{2} - b_{4}} \right)\left( {{- X^{4}} + {2X^{3}} - X^{2}} \right)} + {\left( {a_{3} + a_{4}} \right)\left( {b_{3} + b_{4}} \right)\left( {X^{7} - X^{6} + X^{4} - X^{3}} \right)} + {\left( {a_{0} + a_{1}} \right)\left( {b_{0} + b_{1}} \right)\left( {{- X^{5}} + X^{4} - X^{2} + X} \right)} + {\left( {a_{0} - a_{4}} \right)\left( {b_{0} - b_{4}} \right)\left( {{- X^{6}} + {3X^{5}} - {4X^{4}} + {3X^{3}} - X^{2}} \right)} + {a_{4}{b_{4}\left( {X^{8} - X^{7} + X^{6} - {2X^{5}} + {3X^{4}} - {3X^{3}} + X^{2}} \right)}} + {a_{3}{b_{3}\left( {{- X^{7}} + {2X^{6}} - {2X^{5}} + X^{4}} \right)}} + {a_{1}{b_{1}\left( {X^{4} - {2X^{3}} + {2X^{2}} - X} \right)}} + {a_{0}{b_{0}\left( {X^{6} - {3X^{5}} + {3X^{4}} - {2X^{3}} + X^{2} - X + 1} \right)}}}} & \lbrack 5\rbrack \end{matrix}$

Equation 5 results in 13 products involving coefficients, from (a₀+a₁+a₂+a₃+a₄) (b₀+b₁+b₂+b₃+b₄) to a₀b₀ (from top to bottom of Equation 5). The above equation describes concisely how to take linear combinations of these 13 products to construct all coefficients of the polynomial product a(X)b(X).

Being less concise for the purposes of explanation only (and not limitation), the following are assigned names for the 13 products of Equation 5: p ₀₁₂₃₄=(a ₀ +a ₁ +a ₂ +a ₃ +a ₄)(b ₀ +b ₁ +b ₂ +b ₃ +b ₄) p ₀₂₃₄=(a ₀ −a ₂ −a ₃ −a ₄)(b ₀ −b ₂ −b ₃ −b ₄) p ₀₁₂₄=(a ₀ +a ₁ +a ₂ a ₄)(b ₀ +b ₁ +b ₂ −b ₄) p ₀₁₃₄=(a ₀ +a ₁ −a ₃ −a ₄)(b ₀ +b ₁ −b ₃ −b ₄) p ₀₂₃=(a ₀ −a ₂ −a ₃)(b ₀ −b ₂ −b ₃) p ₁₂₄=(a ₁ +a ₂ −a ₄)(b ₁ +b ₂ −b ₄) p ₃₄=(a ₃ +a ₄)(b ₃ +b ₄) p ₀₁=(a ₀ +a ₁)(b ₀ +b ₁) p ₀₄=(a ₀ −a ₄)(b ₀ −b ₄) p ₄ =a ₄ b ₄ p ₃ =a ₃ b ₃ p ₁ =a ₁ b ₁ p ₀ =a ₀ b ₀.

Substituting these names into Equation 5 and grouping the coefficients of each power of X, produces this:

$\begin{matrix} {{{a(X)}{b(X)}} = {{p_{01234}\left( {X^{5} - X^{4} + X^{3}} \right)} +}} \\ {{p_{0234}\left( {X^{6} - {2X^{5}} + {2X^{4}} - X^{3}} \right)} +} \\ {{p_{0124}\left( {{- X^{5}} + {2X^{4}} - {2X^{3}} + X^{2}} \right)} +} \\ {{p_{0134}\left( {X^{5} - {2X^{4}} + X^{3}} \right)} +} \\ {{p_{023}\left( {{- X^{6}} + {2X^{5}} - X^{4}} \right)} +} \\ {{p_{124}\left( {{- X^{4}} + {2X^{3}} - X^{2}} \right)} +} \\ {{p_{34}\left( {X^{7} - X^{6} + X^{4} - X^{3}} \right)} +} \\ {{p_{01}\left( {{- X^{5}} + X^{4} - X^{2} + X} \right)} +} \\ {{p_{04}\left( {{- X^{6}} + {3X^{5}} - {4X^{4}} + {3X^{3}} - X^{2}} \right)} +} \\ {{p_{4}\left( {X^{8} - X^{7} + X^{6} - {2X^{5}} + {3X^{4}} - {3X^{3}} + X^{2}} \right)} +} \\ {{p_{3}\left( {{- X^{7}} + {2X^{6}} - {2X^{5}} + X^{4}} \right)} +} \\ {{p_{1}\left( {X^{4} - {2X^{3}} + {2X^{2}} - X} \right)} +} \\ {p_{0}\left( {X^{6} - {3X^{5}} + {3X^{4}} - {2X^{3}} + X^{2} - X + 1} \right)} \\ {= {{p_{4}X^{8}} +}} \\ {{\left( {p_{34} - p_{3} - p_{4}} \right)X^{7}} +} \\ {{\left( {p_{0234} - p_{023} - p_{34} - p_{04} + p_{4} + 2_{p\; 3} + p_{0}} \right)X^{6}} +} \\ {\left( {p_{01234} - {2p_{0234}} - p_{0124} + p_{0134} + {2p_{023}} - p_{01} + {3p_{04}} -} \right.} \\ {{\left. {{2p_{4}} - {2p_{3}} - {3p_{0}}} \right)X^{5}} +} \\ {\left( {{- p_{01234}} + {2p_{0234}} + {2p_{0124}} - {2p_{0134}} - p_{023} - p_{124} +} \right.} \\ {{\left. {p_{34} + p_{01} - {4p_{04}} + {3p_{4}} + p_{3} + p_{1} + {3p_{0}}} \right)X^{4}} +} \\ {\left( {p_{01234} - p_{0234} - {2p_{0124}} + p_{0134} + {2p_{124}} - p_{34} + {3p_{04}} -} \right.} \\ {{\left. {{3p_{4}} - {2p_{1}} - {2p_{0}}} \right)X^{3}} +} \\ {{\left( {p_{0124} - p_{124} - p_{01} - p_{04} + p_{4} + {2p_{1}} + p_{0}} \right)X^{2}} +} \\ {{\left( {p_{01} - p_{1} - p_{0}} \right)X} +} \\ {p_{0}.} \end{matrix}$

The immediately above equation written again to just show the final grouping of coefficients:

$\begin{matrix} \begin{matrix} {{{a(X)}{b(X)}} = {{p_{4}X^{8}} +}} \\ {{\left( {p_{34} - p_{3} - p_{4}} \right)X^{7}} +} \\ {{\left( {p_{0234} - p_{023} - p_{34} - p_{04} + p_{4} + {2p_{3}} + p_{0}} \right)X^{6}} +} \\ {\left( {p_{01234} - {2p_{0234}} - p_{0124} + p_{0134} + {2p_{023}} - p_{01} + {3p_{04}} -} \right.} \\ {{\left. {{2p_{4}} - {2p_{3}} - {3p_{0}}} \right)X^{5}} +} \\ {\left( {{- p_{01234}} + {2p_{0234}} + {2p_{0124}} - {2p_{0134}} - p_{023} - p_{124} +} \right.} \\ {p_{34} + p_{01} - {4p_{04}} + {3p_{4}} + p_{3} + p_{1} + {3p_{0}} + X^{4} +} \\ {\left( {p_{01234} - p_{0234} - {2p_{0124}} + p_{0134} + {2p_{124}} - p_{34} +} \right.} \\ {{\left. {{3p_{04}} - {3p_{4}} - {2p_{1}} - {2p_{0}}} \right)X^{3}} +} \\ {{\left( {p_{0124} - p_{124} - p_{01} - p_{04} + p_{4} + {2p_{1}} + p_{0}} \right)X^{2}} +} \\ {{\left( {p_{01} - p_{1} - p_{0}} \right)X} +} \\ {p_{0}.} \end{matrix} & \lbrack 6\rbrack \end{matrix}$

Equation 6 describes concisely how to take linear combinations of these 13 products (p₀₁₂₃₄ to _(p) ₀) to produce the polynomial product of the two 5-term polynomials, a(X) and b(X).

Using this nomenclature, the coefficient of, for example, X⁷ in a(X)b(X) is p ₃₄ −p ₃ −p ₄=(a ₃ +a ₄)(b ₃ +b ₄)−a ₃ b ₃ −a ₄ b ₄ =a ₃ b ₄ +a ₄ b ₃. Methodological Implementation of the Exemplary Karatsuba-Variant Calculator

FIG. 2 shows methodological implementation of the exemplary Karatsuba-variant calculator performed by the Karatsuba-variant calculation unit 130 (or some portion thereof). This methodological implementation may be performed in software, hardware, or a combination thereof. For ease of understanding, the method steps are delineated as separate steps; however, these separately delineated steps should not be construed as necessarily order dependent in their performance.

At 210 of FIG. 2, the exemplary Karatsuba-variant calculator obtains pairs of input polynomials with a maximum of n terms each. The input may include only two polynomials. Alternatively, it can have multiple pairs of polynomials.

At 220, it selects one pair of polynomials, where the two input 5-term polynomials are nominally labeled in accordance with Equations 3 and 4 above.

If the polynomials have a degree other than 4, then they may be processed by other portions of the calculation unit 130 which are configured specifically for polynomials having that degree. Furthermore, polynomials having a degree greater than 4 may be broken down into multiple polynomials where at least one of them has a degree of 4.

At 230, the exemplary Karatsuba-variant calculator computes the product polynomial of these two input 5-term polynomials. It does so by using Equation 5 (or its equivalent Equation 6) above to calculate the product polynomial.

At 240, it determines whether any pair of polynomials remains unselected. If so, then it returns to block 220 to repeat the functions of blocks 220, 230, and 240 for another pair of input polynomials.

If none remain unselected, then it reports the results (product polynomial) at 250.

Exemplary Computing System and Environment

FIG. 3 illustrates an example of a suitable computing environment 300 within which an exemplary Karatsuba-variant calculator, as described herein, may be implemented (either fully or partially). The computing environment 300 may be utilized in the computer and network architectures described herein.

The exemplary computing environment 300 is only one example of a computing environment and is not intended to suggest any limitation as to the scope of use or functionality of the computer and network architectures. Neither should the computing environment 300 be interpreted as having any dependency or requirement relating to any one or combination of components illustrated in the exemplary computing environment 300.

The exemplary Karatsuba-variant calculator may be implemented with numerous other general purpose or special purpose computing system environments or configurations. Examples of well known computing systems, environments, and/or configurations that may be suitable for use include, but are not limited to, personal computers, server computers, thin clients, thick clients, hand-held or laptop devices, smart cards, multiprocessor systems, mobile phones, microprocessor-based systems, set-top boxes, smart cards, programmable consumer electronics, network PCs, minicomputers, mainframe computers, distributed computing environments that include any of the above systems or devices, and the like.

The exemplary Karatsuba-variant calculator may be described in the general context of computer-executable instructions, such as program modules, being executed by a computer. Generally, program modules include routines, programs, objects, components, data structures, etc. that perform particular tasks or implement particular abstract data types. The exemplary Karatsuba-variant calculator may also be practiced in distributed computing environments where tasks are performed by remote processing devices that are linked through a communications network. In a distributed computing environment, program modules may be located in both local and remote computer storage media including memory storage devices.

The computing environment 300 includes a general-purpose computing device in the form of a computer 302. The components of computer 302 may include, by are not limited to, one or more processors or processing units 304, a system memory 306, and a system bus 308 that couples various system components including the processor 304 to the system memory 306.

The system bus 308 represents one or more of any of several types of bus structures, including a memory bus or memory controller, a peripheral bus, an accelerated graphics port, and a processor or local bus using any of a variety of bus architectures. By way of example, such architectures may include an Industry Standard Architecture (ISA) bus, a Micro Channel Architecture (MCA) bus, an Enhanced ISA (EISA) bus, a Video Electronics Standards Association (VESA) local bus, and a Peripheral Component Interconnects (PCI) bus also known as a Mezzanine bus.

Computer 302 typically includes a variety of computer readable media. Such media may be any available media that is accessible by computer 302 and includes both volatile and non-volatile media, removable and non-removable media.

The system memory 306 includes computer readable media in the form of volatile memory, such as random access memory (RAM) 310, and/or non-volatile memory, such as read only memory (ROM) 312. A basic input/output system (BIOS) 314, containing the basic routines that help to transfer information between elements within computer 302, such as during start-up, is stored in ROM 312. RAM 310 typically contains data and/or program modules that are immediately accessible to and/or presently operated on by the processing unit 304.

Computer 302 may also include other removable/non-removable, volatile/non-volatile computer storage media. By way of example, FIG. 3 illustrates a hard disk drive 316 for reading from and writing to a non-removable, non-volatile magnetic media (not shown), a magnetic disk drive 318 for reading from and writing to a removable, non-volatile magnetic disk 320 (e.g., a “floppy disk”), and an optical disk drive 322 for reading from and/or writing to a removable, non-volatile optical disk 324 such as a CD-ROM, DVD-ROM, or other optical media. The hard disk drive 316, magnetic disk drive 318, and optical disk drive 322 are each connected to the system bus 308 by one or more data media interfaces 326. Alternatively, the hard disk drive 316, magnetic disk drive 318, and optical disk drive 322 may be connected to the system bus 308 by one or more interfaces (not shown).

The disk drives and their associated computer-readable media provide non-volatile storage of computer readable instructions, data structures, program modules, and other data for computer 302. Although the example illustrates a hard disk 316, a removable magnetic disk 320, and a removable optical disk 324, it is to be appreciated that other types of computer readable media which may store data that is accessible by a computer, such as magnetic cassettes or other magnetic storage devices, flash memory cards, CD-ROM, digital versatile disks (DVD) or other optical storage, random access memories (RAM), read only memories (ROM), electrically erasable programmable read-only memory (EEPROM), and the like, may also be utilized to implement the exemplary computing system and environment.

Any number of program modules may be stored on the hard disk 316, magnetic disk 320, optical disk 324, ROM 312, and/or RAM 310, including by way of example, an operating system 326, one or more application programs 328, other program modules 330, and program data 332.

A user may enter commands and information into computer 302 via input devices such as a keyboard 334 and a pointing device 336 (e.g., a “mouse”). Other input devices 338 (not shown specifically) may include a microphone, joystick, game pad, satellite dish, serial port, scanner, and/or the like. These and other input devices are connected to the processing unit 304 via input/output interfaces 340 that are coupled to the system bus 308, but may be connected by other interface and bus structures, such as a parallel port, game port, or a universal serial bus (USB).

A monitor 342 or other type of display device may also be connected to the system bus 308 via an interface, such as a video adapter 344. In addition to the monitor 342, other output peripheral devices may include components such as speakers (not shown) and a printer 346 which may be connected to computer 302 via the input/output interfaces 340.

Computer 302 may operate in a networked environment using logical connections to one or more remote computers, such as a remote computing device 348. By way of example, the remote computing device 348 may be a personal computer, portable computer, a server, a router, a network computer, a peer device or other common network node, and the like. The remote computing device 348 is illustrated as a portable computer that may include many or all of the elements and features described herein relative to computer 302.

Logical connections between computer 302 and the remote computer 348 are depicted as a local area network (LAN) 350 and a general wide area network (WAN) 352. Such networking environments are commonplace in offices, enterprise-wide computer networks, intranets, and the Internet.

When implemented in a LAN networking environment, the computer 302 is connected to a local network 350 via a network interface or adapter 354. When implemented in a WAN networking environment, the computer 302 typically includes a modem 356 or other means for establishing communications over the wide network 352. The modem 356, which may be internal or external to computer 302, may be connected to the system bus 308 via the input/output interfaces 340 or other appropriate mechanisms. It is to be appreciated that the illustrated network connections are exemplary and that other means of establishing communication link(s) between the computers 302 and 348 may be employed.

In a networked environment, such as that illustrated with computing environment 300, program modules depicted relative to the computer 302, or portions thereof, may be stored in a remote memory storage device. By way of example, remote application programs 358 reside on a memory device of remote computer 348. For purposes of illustration, application programs and other executable program components such as the operating system are illustrated herein as discrete blocks, although it is recognized that such programs and components reside at various times in different storage components of the computing device 302, and are executed by the data processor(s) of the computer.

Computer-Executable Instructions

An implementation of an exemplary Karatsuba-variant calculator may be described in the general context of computer-executable instructions, such as program modules, executed by one or more computers or other devices. Generally, program modules include routines, programs, objects, components, data structures, etc. that perform particular tasks or implement particular abstract data types. Typically, the functionality of the program modules may be combined or distributed as desired in various embodiments.

Exemplary Operating Environment

FIG. 3 illustrates an example of a suitable operating environment 300 in which an exemplary Karatsuba-variant calculator may be implemented. Specifically, the exemplary Karatsuba-variant calculator(s) described herein may be implemented (wholly or in part) by any program modules 328-330 and/or operating system 326 in FIG. 3 or a portion thereof.

The operating environment is only an example of a suitable operating environment and is not intended to suggest any limitation as to the scope or use of functionality of the exemplary Karatsuba-variant calculator(s) described herein. Other well known computing systems, environments, and/or configurations that are suitable for use include, but are not limited to, personal computers (PCs), server computers, hand-held or laptop devices, multiprocessor systems, microprocessor-based systems, smart cards, programmable consumer electronics, wireless phones and equipments, general- and special-purpose appliances, application-specific integrated circuits (ASICs), network PCs, minicomputers, mainframe computers, distributed computing environments that include any of the above systems or devices, and the like.

Computer Readable Media

An implementation of an exemplary Karatsuba-variant calculator may be stored on or transmitted across some form of computer readable media. Computer readable media may be any available media that may be accessed by a computer. By way of example, and not limitation, computer readable media may comprise “computer storage media” and “communications media.”

“Computer storage media” include volatile and non-volatile, removable and non-removable media implemented in any method or technology for storage of information such as computer readable instructions, data structures, program modules, or other data. Computer storage media include, but are not limited to, RAM, ROM, EEPROM, smart cards, flash memory or other memory technology, CD-ROM, digital versatile disks (DVD) or other optical storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other medium which may be used to store the desired information and which may be accessed by a computer.

“Communication media” typically embodies computer readable instructions, data structures, program modules, or other data in a modulated data signal, such as carrier wave or other transport mechanism. Communication media also includes any information delivery media.

The term “modulated data signal” means a signal that has one or more of its characteristics set or changed in such a manner as to encode information in the signal. By way of example, and not limitation, communication media includes wired media such as a wired network or direct-wired connection, and wireless media such as acoustic, RF, infrared, and other wireless media. Combinations of any of the above are also included within the scope of computer readable media.

CONCLUSION

Although the invention has been described in language specific to structural features and/or methodological steps, it is to be understood that the invention defined in the appended claims is not necessarily limited to the specific features or steps described. Rather, the specific features and steps are disclosed as preferred forms of implementing the claimed invention. 

1. A computer storage medium storing computer-executable instructions that, when executed by a computer, configure the computer as a Karatsuba-variant calculator to electronically secure digital data by performing acts comprising: receiving as input, a pair of polynomials: a(X)=a ₀ +a ₁ X+a ₂ X ² +a ₃ X ³ +a ₄ X ⁴ and b(X)=b ₀ +b ₁ X+b ₂ X ² +b ₃ X ³ +b ₄ X ⁴ computing a product polynomial of the pair of polynomials by calculating (a₀ + a₁ + a₂ + a₃ + a₄)(b₀ + b₁ + b₂ + b₃ + b₄)(X⁵ − X⁴ + X³) + (a₀ − a₂ − a₃ − a₄)(b₀ − b₂ − b₃ − b₄)(X⁶ − 2X⁵ + 2X⁴ − X³) + (a₀ + a₁ + a₂ − a₄)(b₀ + b₁ + b₂ − b₄)(−X⁵ + 2X⁴ − 2X³ + X²) + (a₀ + a₁ − a₃ − a₄)(b₀ + b₁ − b₃ − b₄)(X⁵ − 2X⁴ + X³) + (a₀ − a₂ − a₃)(b₀ − b₂ − b₃)(−X⁶ + 2X⁵ − X⁴) + (a₁ + a₂ − a₄)(b₁ + b₂ − b₄)(−X⁴ + 2X³ − X²) + (a₃ + a₄)(b₃ + b₄)(X⁷ − X⁶ + X⁴ − X³) + (a₀ + a₁)(b₀ + b₁)(−X⁵ + X⁴ − X² + X) + (a₀ − a₄)(b₀ − b₄)(−X⁶ + 3X⁵ − 4X⁴ + 3X³ − X²) + a₄b₄(X⁸ − X⁷ + X⁶ − 2X⁵ + 3X⁴ − 3X³ + X²) + a₃b₃(−X⁷ + 2X⁶ − 2X⁵ + X⁴) + a₁b₁(X⁴ − 2X³ + 2X² − X) + a₀b₀(X⁶ − 3X⁵ + 3X⁴ − 2X³ + X² − X + 1); outputting the product of the pair of polynomials; and electronically securing digital data by using the product of the pair of polynomials.
 2. A computer storage medium as recited in claim 1, wherein the receiving as input, a pair of polynomials comprises: receiving a plurality of pairs of polynomials; and selecting the pair of polynomials from the plurality of pairs of polynomials.
 3. The computer storage medium as recited in claim 2, the method further comprising repeating the selecting and computing for each pair of polynomials of the plurality of pairs of polynomials.
 4. A computer storage medium as recited in claim 1, wherein the method further comprises: replacing variable X by its negative (−X); and replacing the odd-indexed coefficients, a1, a3, b1, b3, by their negatives, −a1, −a3, −b1, −b3, respectively.
 5. A computer storage medium as recited in claim 1, wherein the computing is performed in a finite field of characteristic 2, with each even coefficient being replaced by zero and each odd coefficient being replaced by one.
 6. A computer storage medium as recited in claim 1, wherein the computing is performed in a finite field of characteristic 3, with each coefficient being replaced by its modulo 3 image 0, 1 or −1.
 7. A computer storage medium as recited in claim 1, wherein the pair of polynomials is representative of two integers, A and B, such that: ${A = {{a(R)} = {{\sum\limits_{0 \leq i \leq {n - 1}}^{\;}\;{a_{i}R^{i}\mspace{14mu}{and}\mspace{14mu} B}} = {{b(R)} = {\sum\limits_{0 \leq j \leq {n - 1}}^{\;}\;{b_{j}R^{j}}}}}}},$ where 0≦ai<R and 0≦bj<R.
 8. A computer storage medium as recited in claim 7, wherein j is ≧0 and ≦4.
 9. A computer storage medium as recited in claim 1, wherein the pair of polynomials is representative of two integers base R and length n and wherein X=R in the calculating.
 10. The computer storage medium as recited in claim 1, wherein the product of the pair polynomials represents a product of a pair of large integers, and is utilized within a cryptographic algorithm.
 11. A method comprising: identifying, by a computing system programmed with instructions configuring the computing system to implement a Karatsuba-variant calculator, two input polynomials, a(X) and b(X), each with degree 4 wherein each polynomial is in the variable X, such that: a(X)=a ₀ +a ₁ X+a ₂ X ² +a ₃ X ³ +a ₄ X ⁴; and b(X)=b ₀ +b ₁ X+b ₂ X ² +b ₃ X ³ +b ₄ X ⁴ executing, by the computing system, the Karatsuba-variant calculator on a processor to compute a product polynomial of the two input polynomials by computing (a₀ + a₁ + a₂ + a₃ + a₄)(b₀ + b₁ + b₂ + b₃ + b₄)(X⁵ − X⁴ + X³) + (a₀ − a₂ − a₃ − a₄)(b₀ − b₂ − b₃ − b₄)(X⁶ − 2X⁵ + 2X⁴ − X³) + (a₀ + a₁ + a₂ − a₄)(b₀ + b₁ + b₂ − b₄)(−X⁵ + 2X⁴ − 2X³ + X²) + (a₀ + a₁ − a₃ − a₄)(b₀ + b₁ − b₃ − b₄)(X⁵ − 2X⁴ + X³) + (a₀ − a₂ − a₃)(b₀ − b₂ − b₃)(−X⁶ + 2X⁵ − X⁴) + (a₁ + a₂ − a₄)(b₁ + b₂ − b₄)(−X⁴ + 2X³ − X²) + (a₃ + a₄)(b₃ + b₄)(X⁷ − X⁶ + X⁴ − X³) + (a₀ + a₁)(b₀ + b₁)(−X⁵ + X⁴ − X² + X) + (a₀ − a₄)(b₀ − b₄)(−X⁶ + 3X⁵ − 4X⁴ + 3X³ − X²) + a₄b₄(X⁸ − X⁷ + X⁶ − 2X⁵ + 3X⁴ − 3X³ + X²) + a₃b₃(−X⁷ + 2X⁶ − 2X⁵ + X⁴) + a₁b₁(X⁴ − 2X³ + 2X² − X) + a₀b₀(X⁶ − 3X⁵ + 3X⁴ − 2X³ + X² − X + 1); such that the total number of coefficient multiplication operations is fewer than or equal to 13; reporting, by the computing system, the product polynomial of the two input polynomials; and electronically securing, by the computing system, digital data by using the product polynomial of the two input polynomials.
 12. A method as recited in claim 11, wherein: the identifying comprises selecting, by the computing system, a pair of polynomials from a collection of one or more pairs of polynomials; and the method further comprises repeating, by the computing system, the identifying and computing for each pair of polynomials in the collection of one or more pairs of polynomials.
 13. A method as recited in claim 11, wherein the computing comprises replacing the variable X by its negative (−X) and replacing the odd-indexed coefficients, a₁, a₃, b₁, b₃, by their respective negatives.
 14. A method as recited in claim 11, wherein the computing is performed in a finite field of characteristic 2, by replacing each even coefficient with a zero and replacing each odd coefficient replaced with a one.
 15. A method as recited in claim 11, wherein the computing is performed in a finite field of characteristic 3, by replacing each coefficient coefficient's modulo 3 image 0, 1 or −1.
 16. A method as recited in claim 11, wherein the two input polynomials are respectively representative of integers A and B, wherein: ${A = {{a(R)} = {{\sum\limits_{0 \leq i \leq {n - 1}}^{\;}\;{a_{i}R^{i}\mspace{14mu}{and}\mspace{14mu} B}} = {{b(R)} = {\sum\limits_{0 \leq j \leq {n - 1}}^{\;}\;{b_{j}R^{j}}}}}}},$ and 0≦a_(i)<R and 0≦b_(j)<R.
 17. A system comprising: a processor; a memory; an input unit for receiving two polynomials: a(X)=a ₀ +a ₁ X+a ₂ X ² +a ₃ X ³ +a ₄ X ⁴ and b(X)=b ₀ +b ₁ X+b ₂ X ² +b ₃ X ³ +b ₄ X ⁴ a Karatsuba-variant calculation unit, maintained in the memory and executed on the processor, for computing a product of the polynomials by calculating: (a₀ + a₁ + a₂ + a₃ + a₄)(b₀ + b₁ + b₂ + b₃ + b₄)(X⁵ − X⁴ + X³) + (a₀ − a₂ − a₃ − a₄)(b₀ − b₂ − b₃ − b₄)(X⁶ − 2X⁵ + 2X⁴ − X³) + (a₀ + a₁ + a₂ − a₄)(b₀ + b₁ + b₂ − b₄)(−X⁵ + 2X⁴ − 2X³ + X²) + (a₀ + a₁ − a₃ − a₄)(b₀ + b₁ − b₃ − b₄)(X⁵ − 2X⁴ + X³) + (a₀ − a₂ − a₃)(b₀ − b₂ − b₃)(−X⁶ + 2X⁵ − X⁴) + (a₁ + a₂ − a₄)(b₁ + b₂ − b₄)(−X⁴ + 2X³ − X²) + (a₃ + a₄)(b₃ + b₄)(X⁷ − X⁶ + X⁴ − X³) + (a₀ + a₁)(b₀ + b₁)(−X⁵ + X⁴ − X² + X) + (a₀ − a₄)(b₀ − b₄)(−X⁶ + 3X⁵ − 4X⁴ + 3X³ − X²)a₄b₄(X⁸ − X⁷ + X⁶ − 2X⁵ + 3X⁴ − 3X³ + X²) + a₃b₃(−X⁷ + 2X⁶ − 2X⁵ + X⁴) + a₁b₁(X⁴ − 2X³ + 2X² − X) + a₀b₀(X⁶ − 3X⁵ + 3X⁴ − 2X³ + X² − X + 1);  and an output unit for communicating results from the Karatsuba-variant calculation unit to a data encryption system, whereby the data encryption system uses the results to encrypt data.
 18. A system as recited in claim 17, wherein the Karatsuba-variant calculation unit further computes the product of the polynomials by replacing variable X with its negative (−X) replacing odd-indexed coefficients, a₁, a₃, b₁, b₃, with their respective negatives.
 19. A system as recited in claim 17, wherein the computing is performed in a finite field of characteristic 2, such that the calculating comprises replacing each even coefficient with a zero and replacing each odd coefficient with a one.
 20. A system as recited in claim 17, wherein the computing is performed in a finite field of characteristic 3, such that the calculating comprises replacing each coefficient with its modulo 3 image 0, 1 or −1.
 21. A system as recited in claim 17, wherein the two input polynomials are representative of integers, which are nominally labeled: ${A = {{a(R)} = {{\sum\limits_{0 \leq i \leq {n - 1}}^{\;}\;{a_{i}R^{i}\mspace{14mu}{and}\mspace{14mu} B}} = {{b(R)} = {\sum\limits_{0 \leq j \leq {n - 1}}^{\;}\;{b_{j}R^{j}}}}}}},$ respectively, where 0≦a_(i)<R and 0≦b_(j)<R. 